DISSOLUTION ANALYSIS OF OTC COENZYME Q10 DIETARY SUPPLEMENTS

Yoo, Harrison, Teague, Amanda, Collins, Charles C

05 April 2018

Introduction: Coenzyme Q10 (CoQ10) is a fat-soluble substance (ubiquinone) which has a bright orange color in appearance and is widely distributed (ubiquitous) in animals and many bacteria. CoQ10’s presence is most prevalent in mitochondria and it is involved in aerobic cellular respiration and aides in converting ingested nutrients into a readily accessible form of energy, specifically ATP (adenosine triphosphate). CoQ10 is supplied through our diets and can be found more in dark leafy green vegetables, fish and organ meats. CoQ10 supplementation should be beneficial due to its characteristic antioxidant scavenging of free radicals that our body produces while in the cellular respiration process for generating energy from nutrients. Although CoQ10 has great antioxidant benefit, a challenge remains for supplement manufacturers to deliver a sufficient does of this sparingly soluble molecule. Dietary supplements do not have the significant FDA oversight that exists for legend drugs, resulting in significant variability within and between brands. The main hypothesis of this project is that commercially available CoQ10 supplements don’t deliver a sufficient mass of CoQ10 when compared to the labelled quantity. Methods: To test this hypothesis, the group purchased and tested 14 commercially available CoQ10 supplements with each serving containing 100 mg of active, choosing a variety of drug delivery systems (DDS) and also included one in-house product, which contained 70 mg of active. The DDSs examined consisted of 7 soft shell gelatin (SSG) capsules (the most common type available), 3 hard shell gelatin (HSG) capsules, 3 tablets (tab), 1 powder, and 1 suspension. Each DDS was placed into a 500 mL volumetric flask (VF) into an aqueous of 0.1 N HCl acid and 0.1% Tween 80, using a standard FDA dissolution method. To facilitate drug release, the contents were removed from the HSG capsules; the SSG capsules were perforated; and the tabs were broken/crushed. After this, a magnetic stir bar was placed into each flask and all DDS samples were vigorously stirred for 30-45 minutes, including being inverted every 10 minutes to further facilitate dissolution of CoQ10 from each DDS. Filtered samples were obtained and the samples were analyzed by a reverse-phase High Performance Liquid Chromatography that was previously developed by this research group. Results and Conclusions: Only two of the 15 products evaluated had significant availability (mean > 50%) of CoQ10; one soft gelatin capsule (Product A, dissolved a mean of 68.57%), and the suspension (Product K, dissolved a mean of 56.71%). All of the other products averaged less than 4% dissolution of the labelled amount (range of values 0.19% to 3.64%). The in-house formulated HSG capsule (Product Q) released a mean amount equal to 8.11% of label (more than twice the percentage of the poorly performing commercial products). The consistency of the products was also variable, with product A having a range of 1.7 to 192 mg of CoQ10 released; Product K had a range of 35.8 to 76.1 mg of drug released. The group concluded that there are acceptable products available, but that most have significant performance issues.

Dissolution

CoEnzyme Q10

DDS

Supplement

HPLC

Pharmaceutics and Drug Design

Pharmacy and Pharmaceutical Sciences

Novel Protective Agents against Cerebral Ischemia/Reperfusion Injury.

Xu, Xingshun

15 December 2007

Stroke is the third leading cause of death and disability in the United States. At present, intravenous administration of tissue plasminogen activator (t-PA) is the only thrombolytic therapy approved by the FDA for the treatment of acute ischemic stroke. There are no other effective treatments available so far. The discovery of new drugs and new treatments for stroke to reduce mortality and disability is an urgent medical research priority. In this study, the protective effects and mechanisms of two novel agents Gly14 humanin (HNG) and necrostatin-1 (Nec-1) were examined. HNG, a highly potent neuropeptide against amyloid toxicity, exhibited anti-apoptotic properties on cerebral ischemia injury. HNG reduced infarct volume after ischemia/reperfusion injury with pre-treatment or post-treatment (i.c.v. and i.p.) in a middle cerebral artery occlusion model in mice and decreased neurological deficits induced by ischemia. The protection of HNG was mediated by inhibiting ERK activation and activating PI3K/Akt pathway. Inhibition of the PI3K/Akt pathway blocked the protective effects of HNG. Nec-1 is a specific inhibitor of necroptosis, a newly identified cell death, and was reported to reduce infarct volume even when it was administered at 6 h post-ischemia in a mouse stroke model. Interestingly, this small molecule protected against glutamate-induced oxidative toxicity in a hippocampal HT-22 cell line. It inhibited the translocation of apoptosis-inducing factor from the mitochondria to the nucleus, increased the cellular glutathione level, and decreased free radical formation after glutamate treatment. More importantly, Nec-1 inhibited BNIP3-mediated caspase-independent cell death. Cerebral ischemia/reperfusion injury involves the activation of different pathways that lead to neuronal cell death. Given this multifactorial pathnogenesis, it is possible that a cocktail of neuroprotective agents would be superior to monotherapy. In this study, a cocktail of HNG and Nec-1 was examined in vitro and in vivo. HNG and Nec-1 exerted synergistic neuroprotection on oxygen-glucose deprivation-induced cell death and cerebral ischemia/reperfusion injury. This study provided a new therapeutic strategy for the treatment of stroke by the combination of anti-apoptosis and anti-necroptosis therapy.

Humanin

necrostatin-1

cerebral ischemia

apoptosis

necroptosis

Medicine and Health Sciences

Pharmaceutics and Drug Design

Pharmacy and Pharmaceutical Sciences

Characterization of a 30S Ribsomal Subunit Intermediate Found in <em>Escherichia coli<em> Cells Growing with Neomycin and Paromomycin.

Foster, Cerrone Renee

14 August 2007

The bacterial ribosome is a target for inhibition by numerous antibiotics. Neomycin and paromomycin are aminoglycoside antibiotics that specifically stimulate the misreading of mRNA by binding to the decoding site of 16S rRNA in the 30S ribosomal subunit. Recent work has shown that both antibiotics also inhibit 30S subunit assembly in Escherichia coli and Staphylococcus aureus cells. This work describes the characteristics of an assembly intermediate produced in E.coli cells grown with neomycin or paromomycin. Antibiotic treatment stimulated the accumulation of a 30S assembly precursor with a sedimentation coefficient of 21S. The particle was able to bind radio labeled antibiotics both in vivo and in vitro. Hybridization experiments showed that the 21S precursor particle contained 16S and 17S rRNA. Ten 30S ribosomal proteins were found in the precursor after inhibition by each drug in vivo. In addition, cell free reconstitution assays generated a 21S particle during incubation with either aminoglycoside. Precursor formation was inhibited with increasing drug concentration. This work examines features of a novel antibiotic target for aminoglycoside and will provide information that is needed for the design of more effective antimicrobial agents.

ribosome assembly

aminoglycosides

Escherichia coli

30S subunit

Medicine and Health Sciences

Pharmaceutics and Drug Design

Pharmacy and Pharmaceutical Sciences

COUNTERMEASURES FOR CYANIDE: ORGANOMETALLICS AS NOVEL CYANIDE SCAVENGERS

Matthew Mark Behymer (16558242)

17 July 2023

<p>The objective for this work is to identify and develop an intramuscularly delivered cyanide scavenger. This dissertation outlines in vitro methods which are used to evaluate platinum-based complexes for the potential to scavenge cyanide. Examples of the in vitro techniques used are HPLC, UV-Vis and an ion-selective electrode as orthogonal strategies to monitor cyanide scavenging. Intramuscular formulations for the active platinum-based scavengers are prepared and evaluated for stability. Subsequently, the formulations are tested by collaborating labs for in vivo efficacy. In addition, Sprague Dawley rat studies are employed to investigate the potential toxicity for several platinum complexes. Taken together, this dissertation outlines a short list of novel platinum-based cyanide scavengers as potential alternatives to legacy cobalt-based scavengers. </p>

Pharmaceutical sciences

toxicity

Organometallic Chemistry

HPLC

UV-Vis

Cyanide

Platinum

Kinetics

Nephrotoxicity

Stability

Pharmaceutics

Parenteral formulation

Structure Pharmaceutics Based on Synchrotron Radiation X-Ray Micro- Computed Tomography: From Characterization to Evaluation and Innovation of Pharmaceutical Structures

Yin, Xianzhen

January 2016

Drug delivery systems (DDS) are essentially pharmaceutical products for human therapy, typically involving a mixture of active ingredients and excipients. Based upon quantitative characterization of structure, the thesis introduces the concept of classifying the architecture of DDS into four levels by their spatial scale and the life time period. The primary level is recognised as the static structure of the whole dosage form with a size from μm to cm with the final structure generated by formulation design. The secondary level categorises the structures of particles or sub-units to form a DDS with sizes from nm to mm as key units in processing such as mixing, grinding, granulation and packing; The tertiary level represents the dynamic structures of DDS during the drug release phase in vitro or in vivo incorporating the structure size range from nm to mm, which undergo changes during dissolution, swelling, erosion or diffusion. The spatial scale for the quaternary level is defined as the meso or micro scale architecture of active and non-active molecules within a DDS with sizes from Å to μm for the molecular structure of drug and excipients. Methods combining X-ray tomography, image processing, and 3D reconstructions have been devised and evaluated to study systematically pharmaceutical structures and correlate them with drug release kinetics of DDS. Based on the quantitative structural information of pharmaceutical intermediates and dosage forms, it is possible now to correlate structures with production processing, behaviour and function, and the static and dynamic structures of DDS with the release kinetics. Thus, a structure-guided methodology has been established for the research of DDS. / Chinese Academy of Sciences

Structure

Three dimension

Fractal dimension

Quantitative characterisation

Solid dosage form

Pharmaceutics

PHOSPHATIDYLINOSITOL 3-KINASE (PI3K) AS A THERAPEUTIC TARGET IN NSCLC

Stamatkin, Christopher W.

01 January 2014

Deregulated activation of phosphatidylinositol 3-kinase (PI3K) pathway is central to many human malignancies. The functions of this pathway are critical for normal cell metabolism, proliferation, and survival. In lung cancers, the PI3K pathway activity is often aberrantly driven by multiple mutations, including EGFR, KRAS, and PIK3CA. Molecules targeting the PI3K pathway are intensely investigated as potential anti-cancer agents. Although inhibitors of the pathway are currently in clinical trials, rational and targeted use of these compounds, alone or in combination, requires an understanding of isoform-specific activity in context. We sought to identify class IA PI3K enzyme (p110a/PIK3CA, p110b/PIK3CB, p110d/PIK3CD) activities using isoform-specific inhibitors in a lung cancer model system. Treatment of non-small cell lung cancer (NSCLC) cell lines with PIK3CA, PIK3CB, PIK3CD or PIK3CB/D inhibitors resulted in pharmacokinetic and pharmacodynamic responses that frequently tracked with a specific mutation status. Activation of PIK3CA dictated response to the PIK3CA-specific inhibitor while deletion of PTEN phosphatase indicated response to the PIK3CB inhibitor. The PIK3CD isoform-specific inhibitors lacked efficacy in all NSCLC cell lines tested, however treatment at increased concentrations likely provide concurrent inhibition of both PIK3CB/D isoforms improving activity of either agent alone but did not track with a single biomarker. The observed pharmacodynamic and proliferation responses to isoform-specific inhibitors suggested that PI3K isoforms may functionally compensate for loss of another in certain genetic backgrounds. These studies demonstrate unanticipated cellular responses to PI3K isoform inhibition in NSCLC, suggesting that patient populations with specific mutations can benefit from certain isoform-selective inhibitors, or combinations, allowing for rational and targeted clinical use of these agents.

PI3K

NSCLC

drug discovery

targeted therapy

lung cancer

Medical Cell Biology

Medical Genetics

Medical Pharmacology

Medicinal Chemistry and Pharmaceutics

Oncology

Pharmaceutics and Drug Design

Chemoenzymatic Studies to Enhance the Chemical Space of Natural Products

Chen, Jhong-Min

01 January 2015

Natural products provide some of the most potent anticancer agents and offer a template for new drug design or improvement with the advantage of an enormous chemical space. The overall goal of this thesis research is to enhance the chemical space of two natural products in order to generate novel drugs with better in vivo bioactivities than the original natural products. Polycarcin V (PV) is a gilvocarcin-type antitumor agent with similar structure and comparable bioactivity with the principle compound of this group, gilvocarcin V (GV). Modest modifications of the polyketide-derived tetracyclic core of GV had been accomplished, but the most challenging part was to modify the sugar moiety. In order to solve this problem, PV was used as an alternative lead-structure for modification because its sugar moiety offered the possibility of enzymatic O-methylation. We produced four PV derivatives with different methylation patterns for cytotoxicity assays and provided important structure-activity-relationship information. Mithramycin (MTM) is the most prominent member of the aureolic acid type anticancer agents. Previous work in our laboratory generated three MTM analogues, MTM SA, MTM SK, and MTM SDK by inactivating the mtmW gene. We developed new MTM analogues by coupling many natural and unnatural amino acids to the C-3 side chain of MTM SA via chemical semi-synthesis and successfully made some compounds with both improved bioactivity and in vivo tolerance than MTM. Some of them were consequently identified as promising lead-structures against Ewing’s sarcoma. The potential of selectively generating novel MTM analogues led us to focus on a key enzyme in the biosynthetic pathway of mithramycin, MtmC. This protein is a bifunctional enzyme involved in the biosynthesis of TDP-D-olivose and TDP-D-mycarose. We clarified its enzymatic mechanisms by X-ray diffraction of several crystal complexes of MtmC with its biologically relevant ligands. Two more important post-PKS tailoring enzymes involved in the biosynthesis of the MTM side chains, MtmW and MtmGIV, are currently under investigation. This would not only give us insight into this biosynthetic pathway but also pave the way to develop potentially useful MTM analogues by engineered enzymes.

gilvocarcin V

polycarcin V

mithramycin

MtmC

chemical space

Bacteriology

Biochemistry

Carbohydrates

Enzymes and Coenzymes

Heterocyclic Compounds

Medicinal and Pharmaceutical Chemistry

Medicinal Chemistry and Pharmaceutics

Molecular Biology

Neoplasms

Organic Chemicals

Organic Chemistry

Pharmaceutics and Drug Design

Structural Biology

Engineering of Pharmaceutical Particles : Modulation of Particle Structural Properties, Solid-State Stability and Tabletting Behaviour by the Drying Process

Berggren, Jonas

January 2003

<p>Relationships between stresses during the drying process, particle structural and functional properties, and particle engineering by the drying process were addressed in this thesis. In the first part, the importance of the drying phase and the effect of the drying rate on the intragranular porosity of microcrystalline cellulose pellets were investigated. Differences in porosities of dried pellets could be explained by liquid-related differences in densification during convective drying rather than by differences in densification during wet agglomeration. An increased drying rate gave more porous pellets with a lower compression shear strength, and thereby stronger tablets. The next part dealt with modulation of solid-state stability and tabletting behaviour of amorphous lactose by incorporation of different polymers by spray drying. Increased content and molecular weight of poly(vinylpyrrolidone) (PVP) resulted in an increased resistance to crystallisation provoked by heat and moisture. The stabilising effect was even more evident after long-term storage. However, the glass transition temperature was almost unaffected and may, therefore, be questioned as a stability indicator for these types of materials. The presence of the polymers resulted in somewhat less deformable particles. Incorporation of PVP increased the compactability, whilst a surfactant decreased it, which could be shown to be related to differences in particle-particle adhesivity between the different particles. This thesis contributes to increased mechanistic understanding in the area of particle engineering that may lead to better prediction and optimisation of the functionality of pharmaceutical particles, which is of the utmost importance in the development and production of solid dosage forms.</p>

Pharmaceutics

particle engineering

microcrystalline cellulose pellets

intragranular porosity

convective drying

tabletting behaviour

spray-dried composite particles

amorphous lactose

PVP

glass transition temperature

Galenisk farmaci

Pharmaceutics

Galenisk farmaci

Computational and Experimental Models for the Prediction of Intestinal Drug Solubility and Absorption

Bergström, Christel A. S.

January 2003

<p>New effective experimental techniques in medicinal chemistry and pharmacology have resulted in a vast increase in the number of pharmacologically interesting compounds. However, the number of new drugs undergoing clinical trial has not augmented at the same pace, which in part has been attributed to poor absorption of the compounds.</p><p>The main objective of this thesis was to investigate whether computer-based models devised from calculated molecular descriptors can be used to predict aqueous drug solubility, an important property influencing the absorption process. For this purpose, both experimental and computational studies were performed. A new small-scale shake flask method for experimental solubility determination of crystalline compounds was devised. This method was used to experimentally determine solubility values used for the computational model development and to investigate the pH-dependent solubility of drugs. In the computer-based studies, rapidly calculated molecular descriptors were used to predict aqueous solubility and the melting point, a solid state characteristic of importance for the solubility. To predict the absorption process, drug permeability across the intestinal epithelium was also modeled.</p><p>The results show that high quality solubility data of crystalline compounds can be obtained by the small-scale shake flask method in a microtiter plate format. The experimentally determined pH-dependent solubility profiles deviated largely from the profiles predicted by a traditionally used relationship, highlighting the risk of data extrapolation. The <i>in silico</i> solubility models identified the non-polar surface area and partitioned total surface areas as potential new molecular descriptors for solubility. General solubility models of high accuracy were obtained when combining the surface area descriptors with descriptors for electron distribution, connectivity, flexibility and polarity. The used descriptors proved to be related to the solvation of the molecule rather than to solid state properties. The surface area descriptors were also valid for permeability predictions, and the use of the solubility and permeability models in concert resulted in an excellent theoretical absorption classification. To summarize, the experimental and computational models devised in this thesis are improved absorption screening tools applicable to the lead optimization in the drug discovery process. </p>

Pharmaceutics

aqueous drug solubility

melting point

intestinal drug permeability

pH-dependent solubility

multivariate data analysis

molecular descriptors

molecular surface area

in silico modeling

drug absorption

Galenisk farmaci

Pharmaceutics

Galenisk farmaci

Preparation of Pharmaceutical Powders using Supercritical Fluid Technology : Pharmaceutical Applications and Physicochemical Characterisation of Powders

Velaga, Sitaram P.

January 2004

<p>The main aim of the thesis was to explore the potential of supercritical fluid (SF) techniques in the field of drug delivery. In particular, the relatively recently developed solution-enhanced dispersion by supercritical fluids (SEDS) technology has been employed in the preparation of particles/powders. </p><p>The manufacturing, stability and bioavailability of a dosage form strongly depend on the physicochemical properties of the formulation particles. For example, dry powder inhalation (DPI) for administering drugs to the respiratory tract require particles in a narrow size range (1-5 μm) to be effective. The identification of polymorphs and control of purity are also important issues since the physicochemical properties and therapeutic effects of the alternative forms of a drug may differ substantially. Solvent-based traditional crystallisation processes provide the product that may require further down-stream processing to obtain particles for advanced drug delivery applications. This can result in unwanted changes in the physicochemical properties of the particles and thus affect the performance of the dosage form. SF processing has addressed many of the challenges in particle formation research. Among several SF technologies developed for particle processing over the last decade, the SEDS process with its specially designed co-axial nozzle with mixing chamber has resulted in improved control over the particle formation process. Carbon dioxide (CO₂) was used as the SF, because it has low critical points and is non-toxic, non-flammable and relatively inexpensive. </p><p>The initial part of the thesis concerns the formation of particles of model drugs such as hydrocortisone, budesonide and flunisolide using SEDS technology and the determination of the influence of processing conditions and solvents on particle characteristics such as size, shape and crystal structure. Particles of model drugs of differing shapes in a size range suitable for inhalation delivery were prepared. In the process, two new polymorphic forms of flunisolide were identified. This was the first report of SEDS technology being shown as a polymorph-screening tool. The remainder of the thesis deals with the development of SEDS technology for precipitating therapeutic proteins such as recombinant human growth hormone (hGH) from aqueous solutions. Powders of hGH were precipitated using SEDS without significant changes in the chemical or physical stability of the protein. The addition of sucrose to hGH in the feed solution promoted precipitation and minimised the detrimental effects of the solvent and/or the process on the physical aggregation of the protein. </p><p>In conclusion, this thesis highlights the applicability of the SEDS process in drug delivery research and advances general understanding of the particle formation phenomenon. The SEDS process may also prove to be a potential alternative technology for the precipitation of stable powders of therapeutic proteins.</p>

Pharmaceutics

Supercritical fluid

Gas Anti-Solvent

SEDS

Crystallisation

Particle design

Polymorphs

Dry powder inhalation

Solid-state behaviour

Therapeutic proteins

Precipitation

Stability

Recombinant human growth hormone (hGH)

Galenisk farmaci

Pharmaceutics

Galenisk farmaci